Method and apparatus for operating nonvolatile memory in a parallel arrangement

ABSTRACT

A memory cell with a charge storage structure is read by measuring current between the substrate region of the memory cell and one of the current carrying nodes of the memory cell. The read operation decreases the coupling between different parts of the charge storage structure when other parts of the charge storage structure store data that are not of interest. The sensing window of the memory cell can be greatly improved by this read operation. Example arrangements are a single memory cell, a column or NOR-connected memory cells, and a virtual ground array of memory cells.

RELATED APPLICATIONS

The present application is related to U.S. patent application Ser. No. ______, filed ______ (MXIC 1632-1); U.S. patent application Ser. No. ______, filed ______ (MXIC 1632-2); and U.S. patent application Ser. No. ______, filed ______ (MXIC 1634-1). The present application is a continuation-in-part of U.S. patent application Ser. No. 10/973,593 filed 26 Oct. 2004 (MXIC 1609-2) and is a continuation-in-part of U.S. patent application Ser. No. 10/973,176 filed 26 Oct. 2004 (MXIC 1608-2), which claim the benefit of U.S. Provisional Application No. 60/608,455 filed 9 Sep. 2004 (MXIC 1609-1) and U.S. Provisional Application No. 60/608,528 filed 9 Sep. 2004 (MXIC 1608-1). All these applications are incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to electrically programmable and erasable non-volatile memory, and more particularly to charge storage memory with a bias arrangement that reads the contents of the charge storage structure of the memory cell with great sensitivity.

2. Description of Related Art

Electrically programmable and erasable non-volatile memory technologies based on charge storage structures known as EEPROM and flash memory are used in a variety of modern applications. A number of memory cell structures are used for EEPROM and flash memory. As the dimensions of integrated circuits shrink, greater interest is arising for memory cell structures based on charge trapping dielectric layers, because of the scalability and simplicity of the manufacturing processes. Various memory cell structures based on charge trapping dielectric layers include structures known by the industry names PHINES, NROM, and SONOS, for example. These memory cell structures store data by trapping charge in a charge trapping dielectric layer, such as silicon nitride. As more net negative charge is trapped, the threshold voltage of the memory cell increases. The threshold voltage of the memory cell is reduced by removing negative charge from, or adding positive charge to, the charge trapping layer.

Conventional memory cell structures rely on the reverse read operation to determine the contents of the memory structure. However, the reverse read technique effectively couples together multiple locations of the charge trapping structure, even when only a portion of the charge trapping structure contains data of interest. This dependence constrains the utility of using the charge trapping structure as nonvolatile memory, by narrowing the sensing window of currents measured from the reverse read technique. Less data are stored in the charge trapping structure than otherwise possible.

Power consumption is another area of potential improvement. Portable electronic devices such as music players, cell phones, and wireless devices, have a limited source of power available. The reverse read operation is a source of power drain contributing to power consumption. Similarly, such power consumption occurs in read operations that rely on contrasting levels of lateral current flow through a channel formed in the memory cell.

Thus, a need exists for a nonvolatile memory cell that can be read without suffering substantial coupling between multiple locations of the charge storage structure, even when only a portion of the charge storage structure contains data of interest. Alternately, a need exists for a read operation that reduces power consumption, compared to the reverse read operation.

SUMMARY OF THE INVENTION

A method of operating a nonvolatile memory array, an architecture for an integrated circuit including such a memory array, and an architecture for an integrated circuit including a column nonvolatile memory cells, are disclosed.

A nonvolatile memory integrated circuit includes a nonvolatile memory array storing data as charge storage states, bit lines, word lines providing gate voltage, and controlling logic. The nonvolatile memory array includes columns of memory cells. Each memory cell has a substrate region including first and second current carrying nodes, a charge storage structure, and one or more dielectric structures. The dielectric structure is positioned about the charge storage structure, such that the dielectric structure is interposed somewhere between the charge storage structure and the substrate region, and somewhere between the charge storage structure and the source of gate voltage.

The bit lines couple together the columns of the nonvolatile memory array in a parallel arrangement. The bit lines couple together the first current carrying nodes of in the same columns, such that the first current carrying nodes in a common column share a common potential. Similarly, the bit lines couple together the second current carrying nodes of in the same columns, such that the second current carrying nodes in a common column share a common potential. Also, the bit lines couple together adjacent first current carrying nodes and second current carrying nodes of adjacent columns. Thus, if a second current carrying node in one column is adjacent to a first current carrying node in a second column adjacent to the first column, then the nodes share a common potential.

Logic circuitry applies a read bias arrangement to determine charge storage states of the nonvolatile memory. The logic circuitry measures the resulting current that flows between the substrate and the first current carrying node/second current carrying node. Thus, this measured current is different from alternative read operation currents that flow between the source region and the drain region of the measured memory cell.

Each charge storage state corresponds to the parts of charge storage structures by adjacent first and second current carrying nodes of adjacent columns. For example, when the bit lines and word lines are biased to select a pair of adjacent memory cells straddling a particular bit line and sharing a common word line, then the charge storage state corresponds to parts of charge storage structures by 1) the second current carrying terminal adjacent to the bit line and belonging to one of the pair of memory cells, and 2) the first current carrying terminal adjacent to the bit line and belonging to the other of the pair of memory cells. Each charge storage state stores one bit or multiple bits, depending on the application and design of the memory cell.

In one embodiment, the nonvolatile memory cell has a split gate design, and includes a second gate. In memory operations, the different gates each apply a bias to the substrate region. With this split gate design, the logic applies erase and programming bias arrangements to change the charge storage state by injecting electrons into and ejecting electrons from corresponding parts of the charge storage structures.

In other embodiments, the nonvolatile memory cell has a floating gate design or a nanocrystal design. With this floating gate design or nanocrystal design, the logic applies erase and programming bias arrangements to change the charge storage state by injecting electrons into and ejecting electrons from corresponding parts of the charge storage structures.

In another embodiments, the nonvolatile memory cell has a charge trapping material design. With this charge trapping material design, the logic applies erase and programming bias arrangements to change the charge storage state by injecting electrons into and injection holes into corresponding parts of the charge storage structures.

Because the read operation does not require a current to flow between the first and second current carrying nodes of the measured nonvolatile memory cells, the read bias arrangement allows for one region of the first and second current carrying regions to be floated, while the other region of the first and second current carrying regions is biased to have a voltage difference with the substrate region.

The measured current flowing between the first and/or second current carrying regions, and the substrate region, includes a band-to-band tunneling current, flowing between the substrate region and at least one of the first and second current carrying regions to determine the charge storage state. To induce the measured current flowing between the first and/or second current carrying regions, and the substrate region, the read bias arrangement causes a first voltage difference between the gate and the first and/or second current carrying regions, and a second voltage difference between the first and/or second current carrying regions and the substrate region.

The voltage difference between the gate and at least one of the first and second current carrying regions creates an electric field which causes band bending in the same region(s). The degree of band bending is affected by the charge storage state of the charge trapping structure, resulting in a band-to-band tunneling current in at least one of the first and second current carrying regions that varies with the charge storage state. In some embodiments, the bias arrangement applies a reverse bias voltage difference between the substrate region and the first or second current carrying regions, and floats the other of the first or second current carrying region.

In some embodiments, the substrate region is a well in a semiconductor substrate. In other embodiments, the substrate region is simply the semiconductor substrate.

Other embodiments of the technology described above include a method for operating the nonvolatile memory array, and a column of the nonvolatile memory according to the described technology.

Various embodiments include memory cells with an n-type channel, memory cells with a p-type channel, or memory cells with an n-type channel and memory cells with a p-type channel.

Other aspects and advantages of the technology presented herein can be understood with reference to the figures, the detailed description and the claims, which follow.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a simplified diagram of a charge trapping memory cell, showing a read operation being performed on the portion of the charge trapping structure corresponding to the source side.

FIG. 1B is a simplified diagram of a charge trapping memory cell, showing a read operation being performed on the portion of the charge trapping structure corresponding to the drain side.

FIG. 2A is a graph showing the sensing window of a typical nonvolatile memory cell.

FIG. 2B is a graph showing the sensing window of a memory cell as a program operation is performed on different parts of the charge trapping structure of the memory cell.

FIG. 3A is a simplified diagram of a charge trapping memory cell, showing channel hot electron injection being performed on one portion of the charge trapping structure.

FIG. 3B is a simplified diagram of a charge trapping memory cell, showing channel hot electron injection being performed on another portion of the charge trapping structure.

FIG. 4A is a simplified diagram of a charge trapping memory cell, showing band to band hot hole injection being performed on one portion of the charge trapping structure.

FIG. 4B is a simplified diagram of a charge trapping memory cell, showing band to band hot hole injection being performed on another portion of the charge trapping structure.

FIG. 5 is a diagram of an erase operation via one bias arrangement being performed on a column of nonvolatile memory cells interconnected in a NOR arrangement.

FIG. 6 is a diagram of an erase operation via another bias arrangement being performed on a column of nonvolatile memory cells interconnected in a NOR arrangement.

FIG. 7A is a simplified diagram of a charge trapping memory cell, showing an erase operation being performed on the charge trapping structure, corresponding to FIG. 5.

FIG. 7B is a simplified diagram of a charge trapping memory cell, showing an erase operation being performed on the charge trapping structure, corresponding to FIG. 6.

FIG. 8 is a diagram of a program operation being performed on a column of nonvolatile memory cells interconnected in a NOR arrangement, adding holes to one part of a memory cell.

FIG. 9 is a diagram of a program operation being performed on a column of nonvolatile memory cells interconnected in a NOR arrangement, adding holes to another part of a memory cell.

FIG. 10 is a diagram of a read operation being performed on a column of nonvolatile memory cells interconnected in a NOR arrangement, reading one part of a memory cell.

FIG. 11 is a diagram of a read operation being performed on a column of nonvolatile memory cells interconnected in a NOR arrangement, reading another part of a memory cell.

FIG. 12 is a diagram of an erase operation via one bias arrangement being performed on nonvolatile memory cells interconnected in a virtual ground array arrangement.

FIG. 13 is a diagram of an erase operation via another bias arrangement being performed on nonvolatile memory cells interconnected in a virtual ground array arrangement.

FIG. 14 is a diagram of a program operation being performed on a virtual ground array arrangement of nonvolatile memory cells, adding holes to a part of the virtual ground array.

FIG. 15 is a diagram of a read operation being performed on a virtual ground array arrangement of nonvolatile memory cells.

FIG. 16 is a diagram of an erase operation via one bias arrangement being performed on an array of nonvolatile memory cells interconnected as columns of cells arranged in series.

FIG. 17 is a diagram of an erase operation via another bias arrangement being performed on an array of nonvolatile memory cells interconnected as columns of cells arranged in series.

FIG. 18 is a diagram of an erase operation via one bias arrangement being performed on an array of nonvolatile memory cells interconnected as columns of cells arranged in series with a floating end.

FIG. 19 is a diagram of an erase operation via another bias arrangement being performed on an array of nonvolatile memory cells interconnected as columns of cells arranged in series with a floating end.

FIG. 20 is a diagram of a program operation being performed on an array of nonvolatile memory cells interconnected as columns of cells arranged in series.

FIG. 21 is a diagram of a program operation being performed on an array of nonvolatile memory cells interconnected as columns of cells arranged in series with a floating end.

FIG. 22 is a diagram of a read operation being performed on an array of nonvolatile memory cells interconnected as columns of cells arranged in series, via one end of the series.

FIG. 23 is a diagram of a read operation being performed on an array of nonvolatile memory cells interconnected as columns of cells arranged in series, via another end of the series.

FIG. 24 is a diagram of a read operation being performed on an array of nonvolatile memory cells interconnected as columns of cells arranged in series, via both ends of the series.

FIG. 25 is a diagram of a read operation being performed on an array of nonvolatile memory cells interconnected as columns of cells arranged in series with a floating end.

FIG. 26 is a diagram of an erase operation via one bias arrangement being performed on nonvolatile memory cells interconnected as a column of cells arranged in series.

FIG. 27 is a diagram of an erase operation via another bias arrangement being performed on nonvolatile memory cells interconnected as a column of cells arranged in series.

FIG. 28 is a diagram of an erase operation via one bias arrangement being performed on nonvolatile memory cells interconnected as a column of cells arranged in series with a floating end.

FIG. 29 is a diagram of an erase operation via another bias arrangement being performed on nonvolatile memory cells interconnected as a column of cells arranged in series with a floating end.

FIG. 30 is a diagram of a program operation being performed on nonvolatile memory cells interconnected as a column of cells arranged in series.

FIG. 31 is a diagram of a program operation being performed on nonvolatile memory cells interconnected as a column of cells arranged in series with a floating end.

FIG. 32 is a diagram of a read operation being performed on nonvolatile memory cells interconnected as a column of cells arranged in series, via one end of the series.

FIG. 33 is a diagram of a read operation being performed on nonvolatile memory cells interconnected as a column of cells arranged in series, via another end of the series.

FIG. 34 is a diagram of a read operation being performed on nonvolatile memory cells interconnected as a column of cells arranged in series, via both ends of the series.

FIG. 35 is a diagram of a read operation being performed on nonvolatile memory cells interconnected as a column of cells arranged in series with a floating end.

FIGS. 36A-36C are simplified diagrams of other nonvolatile memory cells with various charge storage structures.

FIG. 37 is a simplified diagram of an integrated circuit with an array of charge trapping memory cells and control circuitry.

DETAILED DESCRIPTION

FIG. 1A is a simplified diagram of a charge trapping memory cell, showing a read operation being performed on the portion of the charge trapping structure corresponding to the source side. The p-doped substrate region 170 includes n+ doped source and drain regions 150 and 160. The remainder of the memory cell includes a bottom dielectric structure 140 on the substrate, a charge trapping structure 130 on the bottom dielectric structure 140 (bottom oxide), a top dielectric structure 120 (top oxide) on the charge trapping structure 130, and a gate 110 on the oxide structure 120. Representative top dielectrics include silicon dioxide and silicon oxynitride having a thickness of about 5 to 10 nanometers, or other similar high dielectric constant materials including for example Al₂O₃. Representative bottom dielectrics include silicon dioxide and silicon oxynitride having a thickness of about 3 to 10 nanometers, or other similar high dielectric constant materials. Representative charge trapping structures include silicon nitride having a thickness of about 3 to 9 nanometers, or other similar high dielectric constant materials, including metal oxides such as Al₂O₃, HfO₂, and others.

The memory cell for SONOS-like cells has, for example, a bottom oxide with a thickness ranging from 2 nanometers to 10 nanometers, a charge trapping layer with a thickness ranging from 2 nanometers to 10 nanometers, and a top oxide with a thickness ranging from 2 nanometers to 15 nanometers. Other charge trapping memory cells are PHINES and NROM.

In some embodiments, the gate comprises a material having a work function greater than the intrinsic work function of n-type silicon, or greater than about 4.1 eV, and preferably greater than about 4.25 eV, including for example greater than about 5 eV. Representative gate materials include p-type poly, TiN, Pt, and other high work function metals and materials. Other materials having a relatively high work function suitable for embodiments of the technology include metals including but not limited to Ru, Ir, Ni, and Co, metal alloys including but not limited to Ru—Ti and Ni-T, metal nitrides, and metal oxides including but not limited to RuO₂. High work function gate materials result in higher injection barriers for electron tunneling than that of the typical n-type polysilicon gate. The injection barrier for n-type polysilicon gates with silicon dioxide as the top dielectric is around 3.15 eV. Thus, embodiments of the present technology use materials for the gate and for the top dielectric having an injection barrier higher than about 3.15 eV, such as higher than about 3.4 eV, and preferably higher than about 4 eV. For p-type polysilicon gates with silicon dioxide top dielectrics, the injection barrier is about 4.25 eV, and the resulting threshold of a converged cell is reduced about 2 volts relative to a cell having an n-type polysilicon gate with a silicon dioxide top dielectric.

In the diagram of FIG. 1A, the source side of the memory cell stores added electrons, for example via a channel reset operation injecting electrons via Fowler-Nordheim tunneling from the gate 110 or the substrate 170, or some other charge movement process such as channel hot electron injection or channel initiated secondary electron injection. The drain side of the memory cell stores added holes, for example via band-to-band hole injection into the drain side of the charge trapping structure 130.

In the bias arrangement of FIG. 1A for reading the source side of the charge trapping structure 130, the voltage of the gate 110 is −10 V, the voltage of the source 150 is 2 V, the voltage of the drain 160 is floating, and the voltage of the substrate 170 is 0 V. The memory cell of FIG. 1B is similar to memory cell of FIG. 1A, except that a read operation is being performed on the drain side of the charge trapping structure rather than on the source side. In the bias arrangement of FIG. 1B for reading the drain side of the charge trapping structure 130, the voltage of the gate 110 is −10 V, the voltage of the source 150 is floating, the voltage of the drain 160 is 2 V, and the voltage of the substrate 170 is 0 V. The bias arrangement is determined among the various terminals, such that the energy bands bend sufficiently to cause band-to-band current in the n+ doped source 150 (FIG. 1A) or the n+ doped drain 160 (FIG. 1B), but to keep the potential difference between the substrate 170 and the source 150 (FIG. 1A) or the drain 160 (FIG. 1B) low enough such that programming or erasing does not occur, as discussed in connection with FIGS. 3A, 3B, 4A, 4B, 7A, and 7B.

In this bias arrangements of FIGS. 1A and 1B, the area of the junction between the p doped substrate 170, and either the n+ doped source 150 or the n+ doped drain 160, displays the behavior of a reverse biased p-n junction. However, the gate voltage causes the energy bands to bend sufficiently such that band-to-band tunneling occurs through the n+ doped source 150 (FIG. 1A) or the n+ doped drain 160 (FIG. 1B). The high doping concentration in the source 150 or the drain 160, the resulting high charge density of the space charge region, and the accompanying short length of the space charge region over which the voltage changes, contribute to the sharp energy band bending. Electrons in the valence band tunnel through the forbidden gap to the conduction band and drift down the potential hill, deeper into either the n+ doped source 150 (FIG. 1A) or the n+ doped drain 160 (FIG. 1B). Similarly, holes drift up the potential hill, away from either the n+ doped source 150 (FIG. 1A) or the n+ doped drain 160 (FIG. 1B), and toward the p doped substrate 170.

The voltage of the gate 110 controls the voltage of the portion of the substrate 170 by the bottom dielectric structure 140 (bottom oxide). In turn, the voltage of the portion of the substrate 170 by the bottom dielectric structure 140 (bottom oxide) controls the degree of band bending between the bottom dielectric structure 140 (bottom oxide), and either the n+ doped source 150 (FIG. 1A) or the n+ doped drain 160 (FIG. 1B). As the voltage of the gate 110 becomes more negative, the voltage of the portion of the substrate 170 by the bottom dielectric structure 140 (bottom oxide) becomes more negative, resulting in deeper band bending in either the n+ doped source 150 (FIG. 1A) or the n+ doped drain 160 (FIG. 1B). More band-to-band current flows, as a result of at least some combination of 1) an increasing overlap between occupied electron energy levels on one side of the bending energy bands, and unoccupied electron energy levels on the other side of bending energy bands, and 2) a narrower barrier width between the occupied electron energy levels and the unoccupied electron energy levels (Sze, Physics of Semiconductor Devices, 1981).

As mentioned above, the drain side of the charge trapping structure 130 is occupied by relatively more holes, whereas the source side of the charge trapping structure 130 is occupied by relatively more electrons than the drain side of the charge trapping structure 130. As a result, in accordance with Gauss's Law, when −10 V is applied to the gate 110, the bottom dielectric structure 140 (bottom oxide) is biased more negatively on the source side than on the drain side. Thus, more current flows between the source 150 and the substrate 170 in the bias arrangement shown in FIG. 1A for reading the source side of the charge trapping structure 130 than flows between the drain 160 and the substrate 170 in the bias arrangement shown in FIG. 1B for reading the drain side of the charge trapping structure 130.

The difference in the bias arrangements of FIGS. 1A and 1B for reading, and the bias arrangement of FIGS. 3A, 3B, 4A, and 4B for programming and erasing, show a careful balance. For reading, the potential difference between the source region and the drain region should not cause a substantial number of carriers to transit the tunnel oxide and affect the charge storage state. In contrast, for programming and erasing, the potential difference between the source region and the drain region is sufficient to cause a substantial number of carriers to transit the tunnel oxide and affect the charge storage state.

FIG. 2A is a graph showing the sensing window of a typical nonvolatile memory cell. In FIG. 2A, the memory cell read by a reverse read operation has a relatively narrow sensing window 250 due to the second bit effect. During the time interval 230, as the first bit is undergoing programming, the read current curve of the first bit 210 increases from a lowest level 260 to a high level 264. Consequently, the programming of the first bit during the time interval 230 substantially affects the read current curve of the second bit 220, which increases from a lowest level 260 to a low level 262. During the time interval 240, as the second bit is undergoing programming, the read current curve of the second bit 220 increases from a low level 262 to a highest level 266. Consequently, the programming of the second bit during the time interval 240 substantially affects the read current curve of the first bit 210, which increases from a high level 264 to a highest level 266. Thus, when performing a reverse read operation on a memory cell on one bit, the resulting read current is substantially affected by the programmed or erased status of the other bit, because for a given gate voltage it becomes more difficult during the reverse read operation to force the substrate portion under the other bit into depletion and inversion, and to punch through the portion of the substrate under the other bit.

FIG. 2B is a graph showing the sensing window of a memory cell as a program operation is performed on different parts of the charge trapping structure of the memory cell. In the graph of FIG. 2B, the first and second charge trapping parts undergo programming. Curve 210 represents the read current of the first charge trapping part. Curve 220 represents the read current of the second charge trapping part. The sensing window 250 shown in FIG. 2B is relatively wide, because the band-to-band read operation is local to either the first terminal or the second terminal. The read current resulting from a band-to-band read operation performed on the first charge trapping part is relatively insensitive to the logical state of the second charge trapping part, and the read current resulting from a band-to-band read operation performed on the second charge trapping part is relatively insensitive to the logical state of the first charge trapping part. The band-to-band read operation is relatively free of the second charge trapping part effect which characterizes the reverse read operation, where the read current resulting from a read operation performed on one side of the charge trapping structure is relatively dependent on the data stored on the other side of the charge trapping structure.

Each charge trapping part can store one bit or multiple bits. For example, if each charge trapping part stores two bits, then there are four discrete levels of charge.

FIGS. 3A and 3B are simplified diagrams of a charge trapping memory cell, showing channel hot electron injection being performed on different portions of the charge trapping structure. In the bias arrangement of FIG. 3A for adding electrons 134 to the source side of the charge trapping structure 130, the voltage of the gate 110 is 10 V, the voltage of the source 150 is 5 V, the voltage of the drain 160 is 0 V, and the voltage of the substrate 170 is 0 V. The memory cell of FIG. 3B is similar to memory cell of FIG. 3A, except that electrons 134 are added to the drain side of the charge trapping structure rather than on the source side. In the bias arrangement of FIG. 3B, the voltage of the gate 110 is 10 V, the voltage of the source 150 is 0 V, the voltage of the drain 160 is 5 V, and the voltage of the substrate 170 is 0 V.

FIGS. 4A and 4B are simplified diagrams of a charge trapping memory cell, showing band to band hot hole injection being performed on different portions of the charge trapping structure. In the bias arrangement of FIG. 4A for adding holes 433 to the drain side of the charge trapping structure 130, the voltage of the gate 110 is −6 V, the voltage of the source 150 is 0 V, the voltage of the drain 160 is 5 V, and the voltage of the substrate 170 is 0 V. The memory cell of FIG. 4B is similar to memory cell of FIG. 4A, except that holes 433 are added to the drain side of the charge trapping structure rather than on the source side. In the bias arrangement of FIG. 4B, the voltage of the gate 110 is −6 V, the voltage of the source 150 is 5 V, the voltage of the drain 160 is 0 V, and the voltage of the substrate 170 is 0 V. In the simplified diagrams of FIGS. 4A and 4B, the stored charge 433 in the charge trapping structure, electrons are symbolically shown smaller than the holes to show that the injected holes have erased previously programmed holes.

In some embodiments, programming refers to making more positive the net charge stored in the charge trapping structure, such as by the addition of holes to or the removal of electrons from the charge trapping; and erasing refers to making more negative the net charge stored in the charge trapping structure, such as by the removal of holes from or the addition of electrons to the charge trapping structure. However, in other embodiments programming refers to making the net charge stored in the charge trapping structure more negative, and erasing refers to making the net charge stored in the charge trapping structure more positive. Various charge movement mechanisms are sued, such as band-to-band tunneling induced hot carrier injection, E-field induced tunneling, channel hot carrier injection, channel initiated substrate carrier injection, and direct tunneling from the substrate.

FIGS. 5 and 6 are diagrams of an erase operation being performed on a column of nonvolatile memory cells interconnected in a NOR arrangement. In the bias arrangement of FIG. 5 for erasing the NOR memory column, the voltages of the word lines 510, 520, 530, and 540 are −8 V; the voltage of the bit lines 504 and 506 are floating, and the voltage of the substrate 502 is 10 V. In the bias arrangement of FIG. 6 for erasing the NOR memory column, the voltages of the word lines 510, 520, 530, and 540 are 8 V; the voltage of the bit lines 504 and 506 are floating, and the voltage of the substrate 502 is −10 V. The bias arrangements of FIGS. 5 and 6 differ in that the electrons tunnel in an overall direction from the gate to the substrate in FIG. 5, and from the substrate to the gate in FIG. 6.

FIGS. 7A and 7B are simplified diagrams of a charge trapping memory cell, showing an erase operation being performed on the charge trapping structure, corresponding to FIGS. 5 and 6. In the bias arrangement of FIG. 7A for erasing the memory cell, the voltage of the gate 110 is −8 V, the voltage of the source 150 and the drain 160 is floating, and the voltage of the substrate 170 is 10 V. The erase operation of FIG. 7A corresponds to the erase operation on the NOR memory column of FIG. 5. The memory cell of FIG. 7B is similar to memory cell of FIG. 7A, except for the direction of movement of the electrons. In the bias arrangement of FIG. 7B, the voltage of the gate 110 is 8 V, the voltage of the source 150 and the drain 160 is floating, and the voltage of the substrate 170 is −10 V. The erase operation of FIG. 7B corresponds to the erase operation on the NOR-connected memory column of FIG. 6. The erase operations of FIGS. 7A and 7B, and the electron injection operation of FIGS. 3A and 3B are alternative electron movement mechanisms.

FIGS. 8 and 9 are diagrams of a program operation being performed on a column of nonvolatile memory cells interconnected in a NOR arrangement. In the bias arrangement of FIG. 8, the voltage of the word lines 510, 530, 540 are 0 V; the voltage of the word line 520 is −5 V; the voltage of the bit line 504 is floating or 0 V; the voltage of the bit line 506 is 5 V; and the voltage of the substrate 502 is 0 V. A hole is symbolically shown being programmed from the bit line 506 into the memory cell controlled by word line 520. In the bias arrangement of FIG. 9, the voltages of the bit lines 504 and 506 are switched, such that the voltage of the bit line 504 is floating or 0 V, and the voltage of the bit line 506 is 5 V. A hole is symbolically shown being programmed from the bit line 504 into the memory cell controlled by word line 520. Thus, the bias arrangement of the bit lines controls the portion of the charge trapping structure that is programmed for a particular memory cell. The operation to add holes to a single cell of FIGS. 4A and 4B is similar to the program operation being performed on the NOR-connected memory column of FIGS. 8 and 9.

FIGS. 10 and 11 are diagrams of a read operation being performed on a column of nonvolatile memory cells interconnected in a NOR arrangement. In the bias arrangement of FIG. 10, the voltage of the word lines 510, 530, 540 are 0 V; the voltage of the word line 520 is −10 V; the voltage of the bit line 504 is 2 V; the voltage of the bit line 506 is floating or 0 V; and the voltage of the substrate 502 is 0 V. A current is symbolically shown flowing from the bit line 504, through the node of the memory cell controlled by word line 520, and into the substrate 502. In the bias arrangement of FIG. 11, the voltages of the bit lines are switched, such that the voltage of the bit line 504 is floating or 0 V, and the voltage of the bit line 506 is 2 V. A current is symbolically shown flowing from the bit line 506, through the node of the memory cell controlled by word line 520, and into the substrate 502. Thus, the bias arrangement of the bit lines controls the portion of the charge trapping structure that is read for a particular memory cell. The read operation being performed on the single cell of FIGS. 1A and 1B is similar to the read operation being performed on the NOR-connected memory column of FIGS. 10 and 11.

FIGS. 12 and 13 are diagrams of an erase operation being performed on nonvolatile memory cells interconnected in a virtual ground array arrangement. In the bias arrangement of FIG. 12, the voltage of the word lines 1210, 1220, 1230, and 1240 are −8 V; the voltage of the bit lines 1203, 1204, 1205, and 1206 is floating; and the voltage of the substrate 1202 is 10 V. The virtual ground array of FIG. 13 is similar to the virtual ground array of FIG. 12, except for the direction of movement of the electrons. In the bias arrangement of FIG. 13, the voltage of the word lines 1210, 1220, 1230, and 1240 are 8 V; the voltage of the bit lines 1203, 1204, 1205, and 1206 is floating; and the voltage of the substrate 1202 is −10 V. The erase operation of FIG. 7A corresponds to the erase operation on the virtual ground array of FIG. 12. The erase operation of FIG. 7B corresponds to the erase operation on the virtual ground array of FIG. 13.

FIG. 14 is a diagram of a program operation being performed on a virtual ground array arrangement of nonvolatile memory cells. In the bias arrangement of FIG. 14, the voltage of the word lines 1210, 1230, and 1240 are 0 V; the voltage of the word line 1220 is −5 V; the voltage of the bit lines 1203, 1204 and 1206 is floating; the voltage of the bit line 1206 is 5 V; and the voltage of the substrate 1202 is 0 V. Holes are symbolically shown being programmed from the bit line 1205 into the parts of the memory cells controlled by word line 1220 and bit line 1205. The operation to add holes of FIGS. 4A and 4B is similar to the program operation of FIG. 14.

FIG. 15 is a diagram of a read operation being performed on a virtual ground array arrangement of nonvolatile memory cells. In the bias arrangement of FIG. 15, the voltage of the word lines 1210, 1230, and 1240 is 0 V; the voltage of the word line 1220 is −10 V; the voltage of the bit line 1204 is 2 V; the voltage of the bit lines 1203, 1205, and 1206 is floating; and the voltage of the substrate 1202 is 0 V. A current is symbolically shown flowing from the bit line 1204, through the memory cells controlled by word line 1220 and bit line 1204, and into the substrate 1202. The read operation being performed in FIGS. 1A and 1B is similar to the read operation of FIG. 15. In some embodiments, a subset of all the bit lines are read.

FIGS. 16 and 17 are diagrams of an erase operation performed on an array of nonvolatile memory cells interconnected as columns of cells arranged in series. In the bias arrangement of FIG. 16, the voltage of the word lines 1620, 1630, 1640, 1650, 1660, 1670, and 1680 is −20 V; the voltage of the word lines 1610 and 1690 is floating; the voltage of the bit lines 1603, 1604, 1605, 1606, and 1607 is floating; and the voltage of the substrate 1602 is 0 V. The memory array of FIG. 17 is similar to the memory array of FIG. 16, except for the direction of movement of the electrons. In the bias arrangement of FIG. 17, the voltage of the word lines 1620, 1630, 1640, 1650, 1660, 1670, and 1680 is 0 V; the voltage of the word lines 1610 and 1690 is floating; the voltage of the bit lines 1603, 1604, 1605, 1606, and 1607 is floating; and the voltage of the substrate 1602 is −20 V. The erase operation of FIG. 7A is similar to the erase operation on the virtual ground array of FIG. 16. The erase operation of FIG. 7B is similar to the erase operation on the virtual ground array of FIG. 17.

FIGS. 18 and 19 are diagrams of an erase operation being performed on an array of nonvolatile memory cells interconnected as columns of cells arranged in series with a floating end. In the bias arrangement of FIG. 18, the voltage of the word lines 1820, 1830, 1840, 1850, 1860, 1870, and 1880 is −20 V; the voltage of the word line 1810 is floating; the voltage of the bit lines 1803, 1804, 1805, 1806, and 1807 is floating; and the voltage of the substrate 1802 is 0 V. The memory array of FIG. 18 is similar to the memory array of FIG. 19, except for the direction of movement of the electrons. In the bias arrangement of FIG. 19, the voltage of the word lines 1820, 1830, 1840, 1850, 1860, 1870, and 1880 is 0 V; the voltage of the word line 1810 is floating; the voltage of the bit lines 1803, 1804, 1805, 1806, and 1807 is floating; and the voltage of the substrate 1802 is −20 V. The erase operation of FIG. 7A is similar to the erase operation on the memory array of FIG. 18. The erase operation of FIG. 7B is similar to the erase operation on the memory array of FIG. 19.

FIG. 20 is a diagram of a program operation being performed on an array of nonvolatile memory cells interconnected as columns of cells arranged in series. In the bias arrangement of FIG. 20, the voltage of the word lines 1620, 1630, 1640, 1650, 1660, 1670, and 1680 are 10 V; the voltage of the word lines 1610 and 1690 is 3 V; the voltage of the bit lines 1603, 1605, and 1606 is 0 V; the voltage of the bit lines 1604 and 1607 is 3 V; and the voltage of the substrate 1602 is 0 V. Electrons are programmed from the bit lines 1603, 1605, and 1606 into the memory cells controlled by both the word line 1640 and the bit lines 1603, 1605, and 1606.

FIG. 21 is a diagram of a program operation being performed on an array of nonvolatile memory cells interconnected as columns of cells arranged in series with a floating end. In the bias arrangement of FIG. 20, the voltage of the word lines 1820, 1830, 1840, 1850, 1860, 1870, and 1880 are 10 V; the voltage of the word line 1810 is 3 V; the voltage of the bit lines 1803, 1805, and 1806 is 0V; the voltage of the bit lines 1804 and 1807 is 3 V; and the voltage of the substrate 1802 is 0 V. Electrons are programmed from the bit lines 1803, 1805, and 1806 into the memory cells controlled by both the word line 1840 and the bit lines 1803, 1805, and 1806.

FIGS. 22, 23, and 24 are diagrams of a read operation being performed on an array of nonvolatile memory cells interconnected as columns of cells arranged in series. In the bias arrangement of FIG. 22, the voltage of the word line 1610 is 3 V; the voltage of the word lines 1620 and 1630 is 10 V; the voltage of the word line 1640 is −10 V; the voltage of the word lines 1650, 1660, 1670, 1680, and 1690 is 0 V; the voltage of the bit lines 1603, 1604, 1605, 1606, and 1607 is 3 V; and the voltage of the substrate 1602 is 0 V. Currents are symbolically shown flowing from the bit lines 1603, 1604, 1605, 1606, and 1607 via the pass transistor row controlled by word line 1610; through the memory cells controlled by word line 1640; and into the substrate 1602. In the bias arrangement of FIG. 23, the voltage of the word lines 1610, 1620, and 1630 is 0 V; the voltage of the word line 1640 is −10 V; the voltage of the word lines 1650, 1660, 1670, and 1680 is 10 V; the voltage of the word line 1690 is 3 V; the voltage of the bit lines 1603, 1604, 1605, 1606, and 1607 is 3 V; and the voltage of the substrate 1602 is 0 V. Currents are symbolically shown flowing from the bit lines 1603, 1604, 1605, 1606, and 1607 via the pass transistor row controlled by word line 1690; through the memory cells controlled by word line 1640; and into the substrate 1602. In the bias arrangement of FIG. 24, the voltage of the word lines 1610 and 1690 is 3 V; the voltage of the word lines 1620, 1630, 1650, 1660, 1670, and 1680 is 10 V; the voltage of the word line 1640 is −10 V; the voltage of the bit lines 1603, 1604, 1605, 1606, and 1607 is 3 V; and the voltage of the substrate 1602 is 0 V. Currents are symbolically shown flowing from the bit lines 1603, 1604, 1605, 1606, and 1607 via the pass transistor rows controlled by word lines 1610 and 1690; through the memory cells controlled by word line 1640; and into the substrate 1602. The read operation being performed in FIGS. 1A and 1B is similar to the read operations of FIGS. 22, 23, and 24. The read current in FIG. 24 flows through both current terminals of the memory cells controlled by word line 1640 into the substrate 1602, whereas the read current in FIGS. 22 and 23 flows through one current terminal of the memory cells controlled by word line 1640 into the substrate 1602. Thus the read current in FIG. 24 is larger than the read current in FIGS. 22 and 23. In some embodiments, a subset of all the bit lines are read.

FIG. 25 is a diagram of a read operation being performed on an array of nonvolatile memory cells interconnected as columns of cells arranged in series with a floating end. In the bias arrangement of FIG. 25, the voltage of the word line 1810 is 3 V; the voltage of the word lines 1820 and 1830 is 10 V; the voltage of the word line 1840 is −10 V; the voltage of the word lines 1850, 1860, 1870, and 1880 is 0 V; the voltage of the bit lines 1803, 1804, 1805, 1806, and 1807 is 3 V; and the voltage of the substrate 1802 is 0 V. Currents are symbolically shown flowing from the bit lines 1803, 1804, 1805, 1806, and 1807 via the pass transistor row controlled by word line 1810; through the memory cells controlled by word line 1840; and into the substrate 1802. In some embodiments, a subset of all the bit lines are read.

FIGS. 26 and 27 are diagrams of an erase operation being performed on nonvolatile memory cells interconnected as a column of cells arranged in series. In the bias arrangement of FIG. 26, the voltage of the gate of memory cells 2620, 2630, 2640, 2650, 2660, 2670, and 2680 is −20 V; the voltage of the gate of memory cells 2610 and 2690 is floating; the voltage of the bit line 2603 is floating; and the voltage of the substrate 2602 is 0 V. The memory column of FIG. 27 is similar to the memory array of FIG. 26, except for the direction of movement of the electrons. In the bias arrangement of FIG. 27, the voltage of the gate of memory cells 2620, 2630, 2640, 2650, 2660, 2670, and 2680 is 0 V; the voltage of the gate of memory cells 2610 and 2690 is floating; the voltage of the bit line 2603 is floating; and the voltage of the substrate 2602 is −20 V. The erase operation of FIG. 7A is similar to the erase operation on the memory column of FIG. 26. The erase operation of FIG. 7B is similar to the erase operation on the memory column of FIG. 17.

FIGS. 28 and 29 are diagrams of an erase operation being performed on nonvolatile memory cells interconnected as a column of cells arranged in series with a floating end. In the bias arrangement of FIG. 28, the voltage of the gate of memory cell 2810 is floating; the voltage of the gates of memory cells 2820, 2830, 2840, 2850, 2860, 2870, and 2880 is −20 V; the voltage of the bit line 2803 is floating; and the voltage of the substrate 2802 is 0 V. The memory column of FIG. 29 is similar to the memory column of FIG. 29, except for the direction of movement of the electrons. In the bias arrangement of FIG. 29, the voltage of the gate of memory cell 2810 is floating; the voltage of the gates of memory cells 2820, 2830, 2840, 2850, 2860, 2870, and 2880 is 0 V; the voltage of the bit line 2803 is floating; and the voltage of the substrate 2802 is −20 V. The erase operation of FIG. 7A is similar to the erase operation on the memory column of FIG. 28. The erase operation of FIG. 7B is similar to the erase operation on the memory column of FIG. 29.

FIG. 30 is a diagram of a program operation being performed on nonvolatile memory cells interconnected as a column of cells arranged in series. In the bias arrangement of FIG. 30, the voltage of the gates of memory cells 2610 and 2690 is 3 V; the voltage of the gates of memory cells 2620, 2630, 2650, 2660, 2670, and 2680 are 10 V; the voltage of the gate of memory cell 2640 is 20 V; the voltage of the bit line 2603 is 0 V; and the voltage of the substrate 2602 is 0 V. Electrons are programmed from the bit line 2603 into the memory cell controlled by the word line 2640.

FIG. 31 is a diagram of a program operation being performed on nonvolatile memory cells interconnected as a column of cells arranged in series with a floating end. In the bias arrangement of FIG. 31, the voltage of the gate of memory cell 2810 is 3 V; the voltage of the gates of memory cells 2820, 2830, 2850, 2860, 2870, and 2880 are 10 V; the voltage of the gate of memory cell 2840 is 20 V; the voltage of the bit line 2803 is 0 V; and the voltage of the substrate 2802 is 0 V. Electrons are programmed from the bit line 2803 into the memory cell controlled by the word line 2840.

FIGS. 32, 33, and 34 are diagrams of a read operation being performed on memory cells interconnected as a column of cells arranged in series. In the bias arrangement of FIG. 32, the voltage of the gate of memory cell 2610 is 3 V; the voltage of the gates of memory cells 2620 and 2630 is 10 V; the voltage of the gate of memory cell 2640 is −10 V; the voltage of the gates of memory cells 2650, 2660, 2670, 2680, and 2690 is 0 V; the voltage of the bit line 2603 is 3 V; and the voltage of the substrate 2602 is 0 V. Current is symbolically shown flowing from the bit line 2603 via the pass transistor 2610; through the memory cell 2640; and into the substrate 2602. In the bias arrangement of FIG. 33, the voltage of the gates of memory cells 2610, 2620, and 2630 is 0 V; the voltage of the gate of memory cell 2640 is −10 V; the voltage of the gates of memory cells 2650, 2660, 2670, and 2680 is 10 V; the voltage of the word line 2690 is 3 V; the voltage of the bit line 2603 is 3 V; and the voltage of the substrate 2602 is 0 V. Current is symbolically shown flowing from the bit line 2603 via the pass transistor 2690; through the memory cell 2640; and into the substrate 2602. In the bias arrangement of FIG. 34, the voltage of the gates of memory cells 2610 and 2690 is 3 V; the voltage of the gates of memory cells 2620, 2630, 2650, 2660, 2670, and 2680 is 10 V; the voltage of the gate of memory cell 2640 is −10 V; the voltage of the bit line 2603 is 3 V; and the voltage of the substrate 2602 is 0 V. Current is symbolically shown flowing from the bit line 2603 via the pass transistors 2610 and 2690; through the memory cell 2640; and into the substrate 2602. The read operation being performed in FIGS. 1A and 1B is similar to the read operations of FIGS. 32, 33, and 34. The read current in FIG. 34 flows through both current terminals of the memory cell 2640 into the substrate 2602, whereas the read current in FIGS. 32 and 33 flows through one current terminal of the memory cell 2640 into the substrate 2602. Thus the read current in FIG. 34 is larger than the read current in FIGS. 32 and 33.

FIG. 35 is a diagram of a read operation being performed on nonvolatile memory cells interconnected as a column of cells arranged in series with a floating end. In the bias arrangement of FIG. 35, the voltage of the gate of memory cell 2810 is 3 V; the voltage of the gates of memory cells 2820 and 2830 is 10 V; the voltage of the gate of memory cell 2840 is −10 V; the voltage of the gates of memory cells 2850, 2860, 2870, and 2880 is 0 V; the voltage of the bit line 2803 is 3 V; and the voltage of the substrate 2802 is 0 V. Current is symbolically shown flowing from the bit line 2803 via the pass transistor 2810; through the memory cell 2840; and into the substrate 2802.

FIGS. 36A-36C show simplified diagrams of other nonvolatile memory cells with various charge storage structures. FIG. 36A shows the structure of a split gate memory cell, with a first gate 1020, a second gate 1010, a charge storage structure 1030, and oxide 1040. FIG. 36B shows a nonvolatile memory cell resembling the nonvolatile memory cell of FIG. 1, but with a floating gate 1030, often made of polysilicon. FIG. 36C shows a nonvolatile memory cell resembling the nonvolatile memory cell of FIG. 1, but with a nanoparticle charge storage structure 1030.

FIG. 37 is a simplified diagram of an integrated circuit with an array of charge trapping memory cells and control circuitry. The integrated circuit 3750 includes a memory array 3700 implemented using nonvolatile memory cells, on a semiconductor substrate. The memory cells of array 3700 may be interconnected in parallel, in series, or in a virtual ground array. A row decoder 3701 is coupled to a plurality of word lines 3702 arranged along rows in the memory array 3700. A column decoder 3703 is coupled to a plurality of bit lines 3704 arranged along columns in the memory array 3700. Addresses are supplied on bus 3705 to column decoder 3703 and row decoder 3701. Sense amplifiers and data-in structures in block 3706 are coupled to the column decoder 3703 via data bus 3707. Data is supplied via the data-in line 3711 from input/output ports on the integrated circuit 3750, or from other data sources internal or external to the integrated circuit 3750, to the data-in structures in block 3706. Data is supplied via the data-out line 3715 from the sense amplifiers in block 3706 to input/output ports on the integrated circuit 3750, or to other data destinations internal or external to the integrated circuit 3750. A bias arrangement state machine 3709 controls the application of bias arrangement supply voltages 3708, such as for the erase verify and program verify voltages, and the arrangements for programming, erasing, and reading the memory cells, such as with the band-to-band currents.

In other embodiments, the select transistors are omitted.

While the present invention is disclosed by reference to the technology and examples detailed above, it is to be understood that these examples are intended in an illustrative rather than in a limiting sense. It is contemplated that modifications and combinations will readily occur to those skilled in the art, which modifications and combinations will be within the spirit of the invention and the scope of the following claims. 

1. A method of operating a nonvolatile memory array storing data as charge storage states, the nonvolatile memory including nonvolatile memory cells arranged in rows and columns, each of the nonvolatile memory cells including a first and a second current carrying node in a substrate region, and including a charge storage structure, and one or more dielectric structures at least partly between the charge storage structure and a source of gate voltage and at least partly between the substrate region and the charge storage structure, the method comprising: applying a read bias arrangement to determine a charge storage state stored in the nonvolatile memory array, including: applying a word line bias to a word line providing a gate voltage to nonvolatile memory cells in a row corresponding to the word line; and applying a bit line bias to a bit line electrically connected to the first current carrying nodes of nonvolatile memory cells in a first column adjacent to the bit line and electrically connected to the second current carrying nodes of nonvolatile memory cells in a second column adjacent to the bit line; and measuring current flowing between the substrate region and the bit line to determine the charge storage state.
 2. The method of claim 1, wherein said applying the read bias arrangement includes: floating bit lines adjacent to the bit line receiving the bit line bias.
 3. The method of claim 1, wherein each of the charge storage states corresponds to parts of the charge storage structure by adjacent first and second current carrying nodes of adjacent columns.
 4. The method of claim 1, wherein each of the charge storage states corresponds to parts of the charge storage structure by adjacent first and second current carrying nodes of adjacent columns, and each of the charge storage states stores multiple bits.
 5. The method of claim 1, wherein each of the charge storage states corresponds to parts of the charge storage structure by adjacent first and second current carrying nodes of adjacent columns, and each of the charge storage states stores a single bit.
 6. The method of claim 1, wherein said applying the read bias arrangement further comprises: applying a second word line bias to a second word line providing a second gate voltage the nonvolatile memory cells in the row.
 7. The method of claim 1, wherein said applying the read bias arrangement further comprises: applying a second word line bias to a second word line providing a second gate voltage the nonvolatile memory cells in the row, and wherein the method further includes: applying erase and programming bias arrangements to change the charge storage states by injecting electrons into and ejecting electrons from corresponding parts of the charge storage structures.
 8. The method of claim 1, wherein the charge storage structure is a floating gate.
 9. The method of claim 1, wherein the charge storage structure is a floating gate, and the method further comprises: applying erase and programming bias arrangements to change the charge storage states by injecting electrons into and ejecting electrons from corresponding parts of the charge storage structures.
 10. The method of claim 1, wherein the charge storage structure is a charge trapping material.
 11. The method of claim 1, wherein the charge storage structure is a charge trapping material, and the method further comprises: applying erase and programming bias arrangements to change the charge storage states by injecting electrons into and injecting holes into corresponding parts of the charge storage structures.
 12. The method of claim 1, wherein the charge storage structure is a nanocrystal material.
 13. The method of claim 1, wherein the charge storage structure is a nanocrystal material, and the method further comprises: applying erase and programming bias arrangements to change the charge storage states by injecting electrons into and ejecting electrons from corresponding parts of the charge storage structures.
 14. The method of claim 1, wherein each of the charge storage states represents multiple data bits.
 15. The method of claim 1, wherein each of the charge storage states represents a single data bit.
 16. The method of claim 1, wherein the read bias arrangement causes a first voltage difference between the word line and the bit line, and a second voltage difference between the substrate region and the bit line, wherein the first voltage difference and the second voltage difference cause sufficient band-to-band tunneling current for said measuring, and the first voltage difference and the second voltage differences fail to change any of the charge storage states.
 17. The method of claim 1, wherein the read bias arrangement induces at least a band-to-band current component.
 18. The method of claim 1, wherein the substrate region is a well in a semiconductor substrate.
 19. A nonvolatile memory integrated circuit, comprising: a nonvolatile memory array storing data as charge storage states, the memory array including a plurality of columns, each column of the plurality of columns including a plurality of memory cells, each memory cell including: a substrate region including a first current carrying node and a second current carrying node; a charge storage structure; and one or more dielectric structures at least partly between the charge storage structure and the substrate region and at least partly between the charge storage structure and a source of gate voltage; a plurality of bit lines coupled to the memory array, the plurality of bit lines coupling together the first current carrying nodes in same columns, the plurality of bit lines coupling together second current carrying nodes in same columns, the plurality of bit lines coupling together adjacent first current carrying nodes and second current carrying nodes of adjacent columns; a plurality of word lines providing the gate voltage to the plurality of memory cells; and logic coupled to the plurality of memory cells, said logic applying a read bias arrangement to determine at least one of the charge storage states and said logic measuring current flowing between the substrate region and at least one of the source region and the drain region to determine at least one of the charge storage states.
 20. The integrated circuit of claim 19, wherein each of the charge storage states corresponds to parts of the charge storage structure by adjacent first and second current carrying nodes of adjacent columns.
 21. The integrated circuit of claim 19, wherein each of the charge storage states corresponds to parts of the charge storage structure by adjacent first and second current carrying nodes of adjacent columns, and each of the charge storage states stores multiple bits.
 22. The integrated circuit of claim 19, wherein each of the charge storage states corresponds to parts of the charge storage structure by adjacent first and second current carrying nodes of adjacent columns, and each of the charge storage states stores a single bit.
 23. The integrated circuit of claim 19, wherein the read bias arrangement applies a voltage difference between the substrate region and at least one of the plurality of bit lines, and floats adjacent bit lines of the plurality of bit lines.
 24. The integrated circuit of claim 19, further comprising: a second plurality of word lines providing a second gate voltage to the plurality of memory cells; wherein at least one bias arrangement applied by the logic applies a first bias to the substrate region of each memory cell via the plurality of word lines and a second bias to the substrate region via the second plurality of word lines, and said logic performs: applying erase and programming bias arrangements to change the charge storage states by injecting electrons into and ejecting electrons from corresponding parts of the charge storage structures.
 25. The integrated circuit of claim 19, wherein the charge storage structure is a floating gate.
 26. The integrated circuit of claim 19, wherein the charge storage structure is a floating gate, and said logic performs: applying erase and programming bias arrangements to change the charge storage states by injecting electrons into and ejecting electrons from corresponding parts of the charge storage structures.
 27. The integrated circuit of claim 19, wherein the charge storage structure is a charge trapping material.
 28. The integrated circuit of claim 19, wherein the charge storage structure is a charge trapping material, and said logic performs: applying erase and programming bias arrangements to change the charge storage states by injecting electrons into and injecting holes into corresponding parts of the charge storage structures.
 29. The integrated circuit of claim 19, wherein the charge storage structure is a nanocrystal material.
 30. The integrated circuit of claim 19, wherein the charge storage structure is a nanocrystal material, and said logic performs: applying erase and programming bias arrangements to change the charge storage states by injecting electrons into and ejecting electrons from corresponding parts of the charge storage structures.
 31. The integrated circuit of claim 19, wherein each of the charge storage states represents multiple data bits.
 32. The integrated circuit of claim 19, wherein each of the charge storage states represents a single data bit.
 33. The integrated circuit of claim 19, wherein the read bias arrangement causes a first voltage difference between the gate and said at least one of the source region and the drain region, and a second voltage difference between said at least one of the source region and the drain region, wherein the first voltage difference and the second voltage difference cause sufficient band-to-band tunneling current for said measuring, and the first voltage difference and the second voltage differences fail to change any of the charge storage states.
 34. The integrated circuit of claim 19, wherein the read bias arrangement induces at least a band-to-band current component through said at least one of the first current carrying node and the second current carrying node.
 35. The integrated circuit of claim 19, wherein said measured current flows through the substrate region, and said at least one of the first current carrying node and the second current carrying node.
 36. The integrated circuit of claim 19, wherein the substrate region is a well in a semiconductor substrate.
 37. A nonvolatile memory integrated circuit, comprising: a plurality of nonvolatile memory cells storing data as charge storage states, each memory cell including: a substrate region including a first current carrying node and a second current carrying node; a charge storage structure; one or more dielectric structures at least partly between the charge storage structure and the substrate region and at least partly between the charge storage structure and a source of gate voltage; and a gate providing the gate voltage; wherein the plurality of memory cells is arranged such that the first current carrying nodes of the plurality of memory cells are coupled together, and the second carrying nodes of the plurality of memory cells are coupled together; and logic coupled to the plurality of memory cells, said logic applying a read bias arrangement to determine at least one of the charge storage states and said logic measuring current flowing between the substrate region and at least one of the first current carrying node and the second current carrying node to determine at least one of the charge storage states.
 38. The integrated circuit of claim 37, wherein the read bias arrangement applies a voltage difference between the substrate region and one of the first current carrying node and the second current carrying node, and floats the other of the first current carrying node and the second current carrying node.
 39. The integrated circuit of claim 37, wherein each memory cell further comprises a second gate, and at least one bias arrangement applied by the logic applies a first bias to the substrate region of each memory cell via the gate of the memory cell and a second bias to the substrate region of each memory cell via the second gate of the memory cell.
 40. The integrated circuit of claim 37, wherein each memory cell further comprises a second gate, and at least one bias arrangement applied by the logic applies a first bias to the substrate region of each memory cell via the gate of the memory cell and a second bias to the substrate region of each memory cell via the second gate of the memory cell, and said logic performs: applying erase and programming bias arrangements to change the charge storage states by injecting electrons into and ejecting electrons from corresponding parts of the charge storage structures.
 41. The integrated circuit of claim 37, wherein the charge storage structure is a floating gate.
 42. The integrated circuit of claim 37, wherein the charge storage structure is a floating gate, and said logic performs: applying erase and programming bias arrangements to change the charge storage states by injecting electrons into and ejecting electrons from corresponding parts of the charge storage structures.
 43. The integrated circuit of claim 37, wherein the charge storage structure is a charge trapping material.
 44. The integrated circuit of claim 37, wherein the charge storage structure is a charge trapping material, and said logic performs: applying erase and programming bias arrangements to change the charge storage states by injecting electrons into and injecting holes into corresponding parts of the charge storage structures.
 45. The integrated circuit of claim 37, wherein the charge storage structure is a nanocrystal material.
 46. The integrated circuit of claim 37, wherein the charge storage structure is a nanocrystal material, and said logic performs: applying erase and programming bias arrangements to change the charge storage states by injecting electrons into and ejecting electrons from corresponding parts of the charge storage structures.
 47. The integrated circuit of claim 37, wherein each of the charge storage states represents multiple data bits.
 48. The integrated circuit of claim 37, wherein each of the charge storage states represents a single data bit.
 49. The integrated circuit of claim 37, wherein the read bias arrangement causes a first voltage difference between the gate and said at least one of the first current carrying node and the second current carrying node, and a second voltage difference between said at least one of the first current carrying node and the second current carrying node, wherein the first voltage difference and the second voltage difference cause sufficient band-to-band tunneling current for said measuring, and the first voltage difference and the second voltage differences fail to change any of the charge storage states.
 50. The integrated circuit of claim 37, wherein the first bias arrangement induces at least a band-to-band current component through said at least one of the first current carrying node and the second current carrying node.
 51. The integrated circuit of claim 37, wherein the substrate region is a well in the semiconductor substrate. 